Influence of Steam Injection during Calcination on the Reactivity of

Article pubs.acs.org/IECR

Influence of Steam Injection during Calcination on the Reactivity of CaO-Based Sorbent for Carbon Capture Scott Champagne,† Dennis Y. Lu,‡ Arturo Macchi,† Robert T. Symonds,‡ and Edward J. Anthony*,‡,§ †

Department of Chemical and Biological Engineering, University of Ottawa, 161 Louis Pasteur Street, Ottawa, Canada K1N 6N5 CanmetENERGY, Natural Resources Canada, 1 Haanel Drive, Ottawa, Canada K1A 1M1

‡

ABSTRACT: Calcium looping is an emerging CO2 capture technology based on cyclic calcination/carbonation reactions using calcium-based sorbents. Steam is typically present in flue/fuel gas streams from combustion or gasification and in the calciner used for sorbent regeneration. The effect of steam in the calciner on sorbent performance has received little attention in the literature. Here, experiments were conducted using a thermogravimetric analyzer (TGA) to determine the effect of steam injection during calcination on sorbent reactivity during carbonation. Two Canadian limestones, Cadomin and Havelock, were tested, and various levels of steam (up to 40%) were injected in the sorbent regeneration process for 15 calcination/carbonation cycles. All concentrations of steam examined were found to increase sorbent reactivity for carbonation for both sorbents. In these experiments, 15% steam concentration with calcination had the largest impact on carrying capacity for both sorbents. Steam changes the morphology of the sorbent while calcination is occurring, probably causing a shift from smaller to larger pores, resulting in a structure which increases carrying capacity. It was also demonstrated that steam addition produced a larger impact on sorbent reactivity for carbonation than for calcination.

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INTRODUCTION Power generation systems using fossil fuels and carbon capture techniques are typically classified into three categories: postcombustion, precombustion, and oxy-fuel combustion. Postcombustion systems employing wet scrubbing of flue gas using liquid amine solutions are thought to be the most commercially promising process for CO2 separation.1,2 However, the drawbacks of wet scrubbing include high energy demand for solvent regeneration (e.g., low process efficiency), relatively high operational and maintenance costs, potential solvent degradation, and solvent instability at high temperature.2,3 In contrast to solvent-based processes, solid sorbentbased processes can be carried out under more flexible operating conditions with higher energy efficiency.4 This work examines the effects of steam on calcium looping, which is usually a high-temperature solid sorbent-based postcombustion CO2 capture technology that employs cyclic calcination/carbonation reactions with calcium-based sorbents.4,5 CaCO3(s) → CaO(s) + CO2 (g)

(1)

CaO(s) + CO2 (g) → CaCO3(s)

(2)

drawback of significant decay in the reactivity of the naturally occurring lime-based sorbents, such as limestone and dolomite, after multiple CO2 capture-and-release cycles.4,8 Phenomena known to influence the sorbent reactivity and conversion include sintering, reaction with flue gas or syngas impurities (primarily sulfur species), and deposition of fuel ash onto the sorbent surface.9−11 In the Ca-looping processes, steam is typically present in the gas streams from either combustion or gasification in the carbonation reactor and from oxy-fuel combustion in the calciner for sorbent regeneration. Therefore, understanding the influence of steam for both calcination and carbonation is essential to understanding sorbent performance. Steam addition in the carbonation step was first examined by Symonds et al.12 for CO2 capture from syngas in a thermogravimetric analyzer (TGA) and at the pilot scale.13 TGA studies were carried out at high enough temperatures to ensure that the steam did not actually react with CaO, as is the case of steam hydration, but nonetheless sorbent performance is improved in the presence of steam and the effect is more pronounced after multiple reaction cycles.15 CaO also enhances the water-gas shift reaction as a catalyst promoting H2 production and enhancing CO2 capture.12 Experiments similar to the previous TGA studies12,15 were repeated in a pilot-scale dual fluidized bed unit and the enhancement of sorbent conversion was confirmed whenever steam was added in the initial fast reaction step of carbonation or even later on (60 min) in the slow diffusioncontrolled carbonation reaction regime.13 This phenomenon may be interpreted in several ways including catalytic

The calcium looping process is promising for either new or retrofit applications for CO2 capture from flue gas. A relatively high-purity CO2 stream is produced in the sorbent regeneration step (calcination) suitable for compression and sequestration. The advantages of such a process, compared to other proposed technologies, include a lower energy penalty, use of mature fluidized bed technology, an inexpensive and nontoxic sorbent derived from limestone, lower operating costs, and potential synergy by using the spent sorbent in the cement industry.6,7 The bench- and pilot-scale work to date indicates that the technology is reliable and promising, but with the major © 2012 American Chemical Society

Received: Revised: Accepted: Published: 2241

May 16, 2012 October 4, 2012 December 28, 2012 December 28, 2012 dx.doi.org/10.1021/ie3012787 | Ind. Eng. Chem. Res. 2013, 52, 2241−2246

Industrial & Engineering Chemistry Research

Article

subsequent complete hydration (CaO → Ca(OH)2) and as well an improved reactivity in the carbonation reaction compared to that for CaO produced without steam. Donat et al.20 examined the effect of steam (1−20%) in calcination for four naturally occurring limestones and reported that steam enhanced sorbent carbonation reactivity at a steam concentration as low as 1%. Above that concentration they observed no further significant effect. The improvement correlates with promoted sintering that actually results in a more stable pore structure for most pores larger than 50 nm in diameter, which typically evolves when no steam is present.22 By comparing the results from the addition of steam in carbonation, they suggested that the changes of sorbent morphology due to the presence of steam in calcination could have a more pronounced influence on sorbent reactivity than the presence of steam in carbonation.20 More work is obviously needed to better understand the mechanisms of the effect of steam on the reactivity of CaO for CO2 capture in the high-temperature calcination/carbonation looping process. This work examines the effects of steam on calcination at concentrations consistent with solid fuel combustion and at higher levels to determine if there is any practical advantage in additional steam injection in the calciner. Results are presented for tests conducted with steam concentrations from 0 to 40% in calcination over 15 cycles.

improvement of the capture process through the hydration of CaO at the surface of sorbent, forming Ca(OH)2 as a transient intermediate since Ca(OH)2 is not thermodynamically stable at typical carbonation temperatures (>600 °C).10 This would explain the increase in macroporosity for the carbonated samples and increased initial CO2 capture due to a prolonged fast reaction phase of carbonation.13 Alternatively, the enhancement of CO2 mobility due to a reduction in diffusion resistance arising from the presence of steam also explains the increased sorbent conversion when steam is added in a carbonation step.12−14 There have been several recent studies on the addition of steam for the carbonation reaction.15−18 Manovic and Anthony15 studied seven limestones with an original size of 250−425 μm and carbonation temperature from 350 to 800 °C in the presence of steam (10−20%) and reported that sorbent reactivity was improved, especially for the most sintered samples, and at relatively low temperature. This finding is attributed to the effect of steam in accelerating solid state diffusion. Dou et al.16 investigated the effect of steam addition in the carbonation reaction in a fixed-bed reactor and reported an improvement of CO2 capture with steam addition. In this case, the authors suggested that the enhancement of sorbent utilization with steam was due to the conversion of CaO to Ca(OH)2 which reacted directly with CO2. Yang and Xiao17 studied the effects of steam addition on CaO carbonation performance in a pressurized TGA. In contrast to Dou et al.,16 these authors reported that steam increased CaO carbonation performance significantly, even if Ca(OH)2 is not formed prior to carbonation. They suggested that this effect should thus be attributed to steam catalysis of the reaction between CaO and CO2. Recently, Arias et al.18 looked at the effect of steam in the initial carbonation period, where the reaction is under the fast kinetic-controlled regime, for two limestone samples at typical carbonation conditions in two TGA systems. Their results showed that while the presence of steam (20%) can improve the overall sorbent performance by increasing conversion with cycling, steam has no influence on the initial reaction rate constant. Similar kinetic rate constant values were obtained with and without steam present in the reacting gas. Similarly, the addition of steam in the sorbent regeneration step has also been examined to simulate the flue gas produced by burning any hydrocarbon fuel for sorbent calcination. Reported data from recent studies showed, in general, a positive influence on sorbent performance by reducing the extent of CaO sintering in the presence of steam.19,20 This contrasts with earlier reports of the negative effect of steam which enhanced sorbent sintering in the calcination reaction.21,22 Borgwardt21 found that, compared to N2, sorbent sintering could be promoted by the addition of other components in the combustion flue gases, including water vapor and carbon dioxide. Each gas strongly augmented the sintering process, and their combined effects were even more severe. Porosity reduction was found to be accelerated by the presence of either H2O or CO2 in the sintering atmosphere and follow the Coble logarithmic law for sintering at 800−1000 °C.21 Recently, Wang et al.19 investigated limestone (250−500 μm) decomposition in an increasingly diluted atmosphere (20− 100% steam in CO2). They reported an increase in calcination conversion over 40 min corresponding to increasing steam concentration for the calcination due to enhanced heat transfer from gas to solid. The CaO produced from steam dilution showed a significant reduction of the time required for

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EXPERIMENTAL SECTION Cadomin (Alberta, Canada) and Havelock (New Brunswick, Canada) limestones were tested at the 250−425 μm particle size range. Tests were also done using a smaller size fraction (45−106 μm) of Cadomin. Table 1 shows the chemical Table 1. Limestone Compositions as Tested (250−425 μm and 45−106 μm size fractions) component (wt %)

Cadomin 45−106 μm

Cadomin 250−425 μm

Havelock 250−425 μm

SiO2 Al2O3 Fe2O3 TiO2 P2O5 CaO MgO SO3 Na2O K2O Ba Sr V Ni Mn Cr Cu Zn LOF

2.09 1.12 0.79 0.07